Hi-Drive addresses a number of key challenges which are currently hindering the progress of developments in vehicle automation. The key aim of the project is to focus on testing and demonstrating automated driving, by improving intelligent vehicle technologies, to cover a large set of traffic environments, not currently achievable. Hi-Drive enables testing of a variety of functionalities, from motorway chauffeur to urban chauffeur, explored in diverse scenarios with heterogeneous driving cultures across Europe. In particular, the Hi-Drive trials will consider European TEN-T corridors and urban nodes in large and medium cities, with a specific attention to demanding, error-prone, conditions. The project’s ambition is to considerably extend the operational design domain (ODD) from the present situation, which frequently demands interventions from the human driver. Therefore, the project concept builds on reaching a widespread and continuous ODD, where automation can operate for longer periods and interoperability is assured across borders and brands. The project also investigates what factors influence user behavior and acceptance, as well as understanding the needs of other road users interacting with these vehicles. The removal of fragmentation in the ODD is expected to give rise to a gradual transition from a conditional operation towards higher levels of automated driving. With these aims, Hi-Drive associates a consortium of 41 European partners with a wide range of interests and capabilities covering the main impact areas which affect users, and the transport system, and enhance societal benefits. The project intends to contribute towards market deployment of automated systems by 2030. All this cannot be achieved by testing only. Accordingly, the work includes outreach activities on business innovation and standardization, plus extended networking with the interested stakeholders, coordinating parallel activities in Europe and overseas.

This project will develop an open standard for heavy-duty fuel-cell modules in terms of size, interfaces, control and test protocols, with the objective of kickstarting the use of fuel cells and hydrogen in the heavy-duty mobility sector, where electrification with batteries is impractical. Multiple modules may be integrated in a system, similar to AA batteries; this will allow using the same modules for multiple sizes. Combined with the standardisation across several sectors (road, offroad, rail, maritime, etc.) represented by participating OEMs, the same modules will address a large pooled market. The size of the market, and the availability of multiple module suppliers (8 in this project alone) will create a fair competition environment where OEMs may choose and change vendors, driving down prices and activating a virtuous cycle through economies of scale and achieving one of the main goals of the FCH JU's Work Programme in the heavy-duty mobility sector. This project will also produce prototypes form 8 leading FC vendors, which will then be thoroughly tested by two independent institutes for compliance with the open standards produced by the project itself. The project will feature significant dissemination and outreach activities, especially towards external OEMs that may become customers of the module suppliers.

As the introduction of automated vehicles becomes feasible, even in urban areas, it will be necessary to investigate their impacts on traffic safety and efficiency. This is particularly true during the early stages of market introduction, where automated vehicles of all SAE levels, connected vehicles (able to communicate via V2X) and conventional vehicles will share the same roads with varying penetration rates. There will be zones and situations on the roads where high automation can be granted, and others where it is not allowed or not possible due to missing sensor inputs, high complexity situations, etc. In the areas where those zones merge many automated vehicles will change their activated level of automation. Therefore, we refer to these areas as “Transition Areas”. TransAID will develop and demonstrate traffic management procedures and protocols to enable smooth coexistence of automated, connected and conventional vehicles especially at Transition Areas. A hierarchical approach will be followed wh

Highly automated vehicles and cooperative ITS technology will get more and more present in the near future. By combining both, guidance of (groups of) such vehicles can considerably improve especially in urban areas. For management of automated vehicles at signalized intersection and corridors, the MAVEN (Managing Automated Vehicles Enhances Network) project will develop infrastructure-assisted platoon organization and negotiation algorithms. These extend and connect vehicle systems for trajectory and maneuver planning and infrastructure systems for adaptive traffic light optimization. Traffic lights adapting their signal timing to facilitate the movement of organized platoons and reversely will yield substantial better utilization of infrastructure capacity, reduction of vehicle delay and reduction of emission. The MAVEN project will build a system prototype for both field tests and extensive modeling for impact assessment, contribute to the development of enabling technologies such as communication standards and high-precision maps, and develop ADAS techniques for inclusion of vulnerable road users. Additionally, MAVEN will include a user assessment and the development of a roadmap for the introduction of vehicle-road automation to support road authorities in understanding changes in their role and the tasks of traffic management systems. Finally, MAVEN will white paper on ‘management of automated vehicles in a smart city environment’ will be written to position the MAVEN results in the broader perspective of passenger transport in smart / future cities and to embed them with smart city principles and technologies as well as service delivery.

Long-haul BEVs and FCEVs need to become more affordable and reliable, more energy efficient, with a longer range per single charge, and a reduced charging time to meet the user’s needs. Next to those, there is a real need to take zero-emission long-haul goods transport in Europe to the next level by executing real-world demonstrations of BEVs and FCEVs spread all over Europe; this also requires that technology soon can deliver on promised benefits (easy handling, similar driving hours & charging/fueling, and high speeds, and ability to operate in complex transport supply chains); flexible and abundant charging points for the rising number of vehicles must be implemented fast and to support this, novel charging concepts are needed. In addition, as multiple needs in the logistics chain exist, require novel tools for fleet managers providing them with better information on ZEV in logistic operation, providing a twin of the real use thereby giving valuable information regarding predictive maintenance, eco-driving etc., providing information on better logistics planning, the (available) charging and refuelling along the route, access to roads and traffic information. ZEFES major outcomes: Executing of real-world demonstrations of long-haul BEVs and FCEVs across Europe to take zero-emission long-haul goods transport in Europe to the next level. Pathway for long-haul BEVs and FCEVs to become more affordable and reliable, more energy efficient, with a longer range per single charge and reduced charging times able to meet the user’s needs. Technologies which can deliver promised benefits (easy handling, similar driving hours & charging/fueling, high speeds and ability to operate in complex transport supply chains). Mapping of flexible and abundant charging/fueling points and novel charging concepts. Novel tools for fleet management to support the rising number of long-haul BEVs and FCEVs vehicles in the logistics supply chains.